Energy Science and Technology

A cationic polymeric alcohol anti-sloughing agent YPVA with well anti-sloughing function and lower side effect of increasing viscosity was developed through modifying the polymeric alcohol (PVA). Degrade PVA firstly, then make the degraded PVA have action groups. It was proved that the modified PVA has ortho-nitrogen radicals by molecular structure analysis through infrared spectrum. Then the anti-sloughing mechanisms of YPVA were investigated deeply through experiments such as rolling and dispersing recovery, zeta potential and particle size distribution measuring, adsorption and pressure transmission. The anti-sloughing mechanisms are mainly as follows: prevent mud shale particles to hydrate and disperse by adsorbing and coating; holdback mud shale particles to hydrate through altering their surface charge and compressing their diffused double layer after adsorbing on them; pressure and block filtrate transfer through forming film and covering on the surface of slits and pores after adsorbing on the surface of rock in the stratum.

Borehole wall stability; Shale; Cationic polymeric alcohol; Modification; Anti-sloughing mechanisms

A.K. Wojtanowicz. Environmental Control of Drilling Fluids and Produced Water. Department of Petroleum Engineering, Louisiana State University, Baton Rouge, LA 70803-6417, USA.
Blend R (1992). Water based glycol systems acceptable substitute for oil-based muds. Oil & Gas Journal, 90(28), 54-59.
Guohua Wu (1995). Investigation on the modification of polymeric alcohol. Journal of Anhui Institute of Technology, 14(3), 51-54.
Hanyi Zhong, Zhengsong Qiu, Weian Huang, Jie Cao (2011). Shale inhibitive properties of polyether diamine in water-based drilling fluid. Journal of Petroleum Science and Engineering, 78(2), 510–515.
Jiafang Xu, Zhengsong Qiu, Kaihe Lü, Lianxiang Yu (2007). Anti sloughing mechanism of silicate drilling fluid and its application technology. Petroleum exploration and development, 34(5), 622-627.
Jiafang Xu, Zhengsong Qiu, Kaihe Lü (2005). Pressure transmission testing technology and simulation equipment for hydra-mechanics coupling of shale. Acta Petroleui Sinica, 26(6), 115-118.
Jiafang Xu, Zhengsong Qiu (2006). Simulation test equipment of coupled hydra-mechanics of shales. Journal of China University of Petroleum, 30(3), 63-66.
Lewen Zhang, Daohong Qiu, Yuanfang Cheng (2009). Research on the wellbore stability model coupled mechanics and chemistry. Journal of Shandong university (engineering science), 39(3), 111-114.
Li hui Zheng, Jienian Yan, Mian chen, WeiXiang Cui (2005). Performance Properties and Functioning Mechanisms of Pseudo Sulfonated Asphalt as Anticaving Agent for Water Base Drilling Fluids. Oilfield Chemistry, 22(2), 97-100.
Patel, A.D. (2009). Design and development of quaternary amine compounds: shale inhibition with improved environmental profile. SPE Paper 121737, SPE International Symposium on Oilfield Chemistry. Woodlands, Texas, 20-22 April.
Patel, A.D., Stamatakis, E., Young, S., Friedeim, J. (2007). Advances in inhibitive water-based drilling fluids-can they replace oil-based muds? SPE Paper 106476, SPE International Symposium on Oilfield Chemistry. Houston, Texas, 28 February- 2 March.
Recommended Practice (1988). Standard procedure for field testing drilling fluids, 12th ed. API, Washington, USA. Recommended Practice, 13(B) (RP 13B), 7-9.
Robert, D. Brown (1990). Newly instrumental technique pan. Translated by chemistry department of Peking University. Chemical industry publishing company. 226-273. R.Schlemmer, J.E. Friedheim, F.B. Growcock, M-I L.L.C., J.B. Bloys, J.A. Headley, and S.C. Polnaszek (2003). Chemical Osmosis, Shale, and Drilling Fluids. SPE paper 86912, SPE Drilling & Completion Conference, December.
Sarkyt Kudaibergenov, Werner Jaeger, Andre Laschewsky (2006). Polymeric Betaines: Synthesis, Characterization, and Application. Adv Polym Sci (Published online), 201, 157-224.
Seyed Mohsen Samaei, Koorosh Tahmasbi (2007). The Possibility of Replacing Oil-Based Mud With the Environmentally Acceptable Water-Based Glycol Drilling Mud for the Iranian Fields. SPE paper 106419, SPE E&P Environmental and Safety Conference held in Galveston, Texas, U.S.A, 5-7 March.
Shyam Kumar, Jnan Kachari (2010). Use of KCl-Polymer Clouding Out Polyol Drilling Fluid in Combating High Pressure in Deep Exploratory Wells of Assam Field A Case Study. SPE paper 128849, SPE Oil and Gas India Conference and Exhibition held in Mumbai, India, 20-22 January.
Steven Yong, Gamal Ramses (2006). Drilling Performance and Environmental Compliance Resolution of Both with a Unique Water-Based Fluid. SPE paper 103967. SPE/IADC Indian Drilling Technology Conference and Exhibition held in Mumbai, India, 16-18 October.
Watson, P., Meize, B., Aldea, C., Blackwell, B. (2004). Eastern Gulf of Mexico: inhibitive water-based drilling fluid sets ultra-deepwater records. IADC/SPE Paper 87131, IADC/SPE Drilling Conference. Dallas, Texas, 2–4 March.
Wenfa Xiao, Xingjin Xiang, Changjun Wang, Xia Zhao, Chunzhi Luo, Shaojin Yi (1998). A Study of Adsorption of JLX Water-based Anti-sloughing Lubricant on the Surface of Clay Grains. Journal of Jianghan Petroleum Institute, 20(1), 1-4.
Young, S., Maas, Ton Maas, Noviant, B.V., Nijmegen (2001). Novel polymer chemistry increases shale stability. AADE National Drilling Technical Conference, AADE 01-NC-HO-41. Houston, Texas, 27–29 March.